Abstract: Described herein are fabrication processes and resulting transistor arrangements with trench contacts that have two parts—a first trench contact (TCN1) and a second trench contact (TCN2)—stacked over one another, and with gate contacts (VCGs). In such transistor arrangements, the TCN1 may be self-aligned to adjacent gates and may be used to make cell-level connections, the TCN2 may also make cell-level connections and may be provided after the self-aligned TCN1 formation and may have an inverse taper shape, the spacer around the TCN2 may be a higher dielectric constant dielectric material than conventional spacer materials, and the VCGs may be formed without the presence of any gate caps or after using only thin temporary gate caps. Fabrication processes and transistor arrangement described herein may provide several improvements in terms of increased edge placement error margin, cost-efficiency, and device performance.

Abstract: A thermo-optic device may be formed with trenches that undercut the substrate beneath the thermo-optic device. Through the removal of the underlying substrate, the heat dissipation of the thermo-optic device may be reduced. This may reduce the thermal budget of the device, reducing the power requirements for operating the device in some embodiments.

Abstract: A thermo-optic device may be formed with trenches that undercut the substrate beneath the thermo-optic device. Through the removal of the underlying substrate, the heat dissipation of the thermo-optic device may be reduced. This may reduce the thermal budget of the device, reducing the power requirements for operating the device in some embodiments.

Abstract: A thermo-optic device may be formed with trenches that undercut the substrate beneath the thermo-optic device. Through the removal of the underlying substrate, the heat dissipation of the thermo-optic device may be reduced. This may reduce the thermal budget of the device, reducing the power requirements for operating the device in some embodiments.

Abstract: Electron emission structures formed using standard semiconductor processes on a substrate first prepared with a topographical feature are disclosed. At least one layer of a first material is concurrently deposited on the substrate and etched from the substrate to form an atomically sharp feature. An at least one layer of a second material is deposited over the atomically sharp feature. A conductive layer is deposited over the at least one layer of the second material. A selected area of material is removed from the conductive layer and the at least one layer of second material to expose the atomically sharp feature. Finally, electrical connectivity is provided to elements of the electron emission structure.

Abstract: Electron emission structures formed using standard semiconductor processes on a substrate first prepared with a topographical feature are disclosed. At least one layer of a first material is concurrently deposited on the substrate and etched from the substrate to form an atomically sharp feature. An at least one layer of a second material is deposited over the atomically sharp feature. A conductive layer is deposited over the at least one layer of the second material. A selected area of material is removed from the conductive layer and the at least one layer of second material to expose the atomically sharp feature. Finally, electrical connectivity is provided to elements of the electron emission structure.

Abstract: Electron emission structures formed using standard semiconductor processes on a substrate first prepared with a topographical feature are disclosed. At least one layer of a first material is concurrently deposited on the substrate and etched from the substrate to form an atomically sharp feature. An at least one layer of a second material is deposited over the atomically sharp feature. A conductive layer is deposited over the at least one layer of the second material. A selected area of material is removed from the conductive layer and the at least one layer of second material to expose the atomically sharp feature. Finally, electrical connectivity is provided to elements of the electron emission structure.

Abstract: Electron emission structures formed using standard semiconductor processes on a substrate first prepared with a topographical feature are disclosed. At least one layer of a first material is concurrently deposited on the substrate and etched from the substrate to form an atomically sharp feature. An at least one layer of a second material is deposited over the atomically sharp feature. A conductive layer is deposited over the at least one layer of the second material. A selected area of material is removed from the conductive layer and the at least one layer of second material to expose the atomically sharp feature. Finally, electrical connectivity is provided to elements of the electron emission structure.